KR101613622B1 - Multi-function Circulation Type Anaerobic Digestion Device - Google Patents

Abstract

The present invention relates to an anaerobic treatment apparatus which is applied to an equipment treating leachate generated from food waste. The anaerobic treatment apparatus comprises: a first acid fermentation tank (100) which performs acid fermentation on food waste leachate supplied from a food waste leachate sump through microorganisms for acid fermentation; a second acid fermentation tank (200) which performs acid fermentation on food waste leachate supplied from the food waste leachate sump through microorganisms for acid fermentation; a first anaerobic digestion tank (300) which receives food waste leachate treated by passing through the first acid fermentation tank (100) and has a reaction between food waste leachate with anaerobic microorganisms; and a second anaerobic digestion tank (400) which receives food waste leachate treated by passing through the second acid fermentation tank (200) and has a reaction between food waste leachate with anaerobic microorganisms. The acid fermentation tank and the anaerobic digestion tank are connected by pairs in parallel, and thus the anaerobic treatment apparatus can be continuously maintained even during maintenance operations such as repairing a broken apparatus or replacing parts without completely shutting down the operation of the apparatus.

Description

[0001] The present invention relates to an anaerobic treatment apparatus using a multifunctional suction cycle,

(50% operation) without stopping the operation of the apparatus entirely even if maintenance work such as repair of the apparatus or maintenance work such as replacement of the parts is performed, in which the acid fermenter and the anaerobic digester are arranged in parallel for each two, .

Anaerobic digestion refers to a process in which organic matter biologically degradable by anaerobic microorganisms undergoes a stepwise chemical reaction and is finally decomposed into methane (CH ₄ ) and carbon dioxide (CO ₂ ) under oxygen-free conditions.

The anaerobic digestion process was approached to the environmental field by the reduction of sewage sludge from 1900, and it was applied to the waste wastewater treatment such as yeast production wastewater in the late 1950s. Since then, active research has been carried out for the purpose of energy recovery from organic wastes, because of the advantages of energy production compared to fossil energy alternatives and aerobic treatment methods in the mid-1970s due to the energy crisis.

In anaerobic digestion, more than 90% of the influent substrate is converted into biogas without the oxygen supply, it can treat high concentration of substrate, and the amount of sludge is about 4%. On the other hand, anaerobic digestion is more complicated than aerobic reaction, and microbes are sensitive to environmental factors and because of the low growth rate of anaerobic microorganisms, long residence time is required to metabolize the influent substrate. Further, since the concentration of the final treated water is high, subsequent treatment is required, the sedimentability of the sludge is low, and odor is generated.

Organic decomposition of anaerobic digestion is divided into several stages by each anaerobic microorganism. The anaerobic digestion process consists of a hydrolysis step in which a substance with a high molecular weight is converted into a substance that is easy to be used as energy and a cell carbon source, a step in which a compound produced in the hydrolysis step is converted into a low molecular weight intermediate compound ), And a methanogenesis step of converting the intermediate compound generated in the organic acid production step into methane and carbon dioxide gas. The organic acid fermentation step can be divided into an acid fermentation step and an acetic acid fermentation step.

A specific embodiment of an anaerobic digestion treatment apparatus for treating organic wastes using anaerobic digestion is disclosed in Korean Patent Registration No. 1049069 (registered on July 07, 2011). The anaerobic digestion apparatus disclosed in the above publication includes an integrated anaerobic digestion tank for biologically treating organic wastes with anaerobic microorganisms and storing biogas generated during the anaerobic digestion process, and a plurality of mechanical stirrers installed in the anaerobic digestion tank In the conventional anaerobic digestion apparatus, the anaerobic digestion efficiency is low because all stages of anaerobic digestion are performed in one anaerobic digestion tank, and the agitator installed in the anaerobic digestion tank is made of a mechanical type including an underwater motor and a rotary screw, Of course, there is a high possibility of occurrence of a fault, and there is a problem that the operation of the apparatus must be stopped completely for troubleshooting.

In order to solve the above problems, the technical composition of the present invention is as follows.

First, the acid fermentation tank and the anaerobic digestion tank are separated from each other to increase the treatment efficiency. In addition, two acid fermentation tanks and anaerobic digestion tank are connected in parallel to each other to maintain the operation of the device without stopping entirely It is an object of the present invention to provide a new anaerobic digester.

Another object of the present invention is to provide a new anaerobic digestion device capable of controlling the operation PH of the acid fermentation tank without adding any additional chemicals by providing a return line from the anaerobic digestion tank to the acid fermentation tank.

Third, a plurality of suction lines are uniformly installed in the anaerobic digestion tank, and the automatic valve installed in each suction line is crossed open to enhance the flow of the wastewater circulating in the anaerobic digestion tank, so that the sludge is not deposited on the bottom surface of the anaerobic digestion tank It is another object of the present invention to maximize the stirring efficiency by circulating with the waste water.

Technical features of the present invention are as follows.

The present invention relates to an anaerobic treatment apparatus applied to a facility for treating leachate generated from food wastes (negative wastewater), comprising a first acid fermentation tank for acidic fermentation of acidic wastewater supplied from a wastewater collection tank through an acid fermentation microorganism 100); A second acid fermentation tank 200 for acidic fermentation of the wastewater supplied from the waste water collection tank through the acid fermentation microorganisms; A first anaerobic digestion tank (300) for receiving negative fermentation treated wastewater through the first acid fermentation tank (100) and reacting with anaerobic microorganisms; A second anaerobic digestion tank (400) for receiving the acidic fermentation treated wastewater while passing through the second acid fermentation tank (200) and reacting with the anaerobic microorganism; A first anaerobic digestion tank injection pump 110 for supplying the wastewater from the first acid fermentation tank 100 to the first anaerobic digestion tank 300; A second anaerobic digester tank infusion pump 210 for supplying the waste water from the second acid fermentation tank 200 to the second anaerobic digestion tank 400; A first underwater stirrer 120 installed under the inner space of the first acid fermentation tank 100 to stir the waste water; A second underwater stirrer 220 installed under the inner space of the second acid fermentation tank 200 to stir the waste water; A first anaerobic digestion tank circulation pump 310 for sucking the wastewater from the lower part of the inner space of the first anaerobic digestion tank 300 and supplying the sucked wastewater to the upper part of the inner space of the first anaerobic digestion tank 300; A first suction line part 320 connected to the inlet side of the first anaerobic digestion tank circulation pump 310 at one end, and a lower end installed at the lower part of the inner space of the first anaerobic digestion tank 300; A first supply line unit 330 connected at one end to the outlet of the first anaerobic digestion tank circulation pump 310 and at the other end installed above the interior space of the first anaerobic digestion tank 300; A second anaerobic digestion tank circulation pump 410 for sucking the wastewater from the lower part of the inner space of the second anaerobic digestion tank 400 and supplying it to the upper part of the inner space of the second anaerobic digestion tank 400; A second suction line part 420 connected at one end to the inlet side of the second anaerobic digestion tank circulation pump 410 and at the other end below the internal space of the second anaerobic digestion tank 400; A second supply line part 430 connected to the outlet side of the second anaerobic digestion tank circulation pump 410 at one end and installed at the upper part of the internal space of the second anaerobic digestion tank 400 at the other end; A first branch line (340) branched from the first supply line part (330) and connected to an upper part of the inner space of the second anaerobic digestion tank (400); A first opening / closing valve (345) installed in the first branch line (340) for opening / closing the first branch line (340); A second branch line 440 branched from the second supply line unit 430 and connected to an upper portion of the inner space of the first anaerobic digestion tank 300; A second open / close valve (445) installed in the second branch line (440) for opening / closing the second branch line (440); One end of the first anaerobic digestion tank 300 is connected to the first feed line 330 and the other end of the first anaerobic digestion tank 300 is installed above the inner space of the first acid fermentation tank 100, A first conveying line 350 for conveying the toner image to the recording medium 100; And one end of the second anaerobic digestion tank 400 is connected to the second supply line unit 430 and the other end of the second anaerobic digestion tank 400 is installed above the inner space of the second acid fermentation tank 200, And a second transfer line (450) for transferring the fermented milk to an acid fermentation tank (200).

Technical effects of the configuration of the present invention are as follows.

First, the process efficiency of the acid fermentation tank (100, 200) and the anaerobic digestion tank (300, 400) was improved. In addition, in the process of maintenance of the treatment device, two acid fermentation tanks (100, 200) and two anaerobic digestion tanks It is possible to keep the operation of the apparatus without stopping the whole operation.

Second, the transfer lines 350 and 450 are installed in the anaerobic digestion tanks 300 and 400 to the acid fermentation tanks 100 and 200, respectively, so that the operating pH of the acid fermentation tank can be adjusted without adding any additional chemicals.

Third, a plurality of suction lines 321 and 421 are uniformly installed in the anaerobic digestion tanks 300 and 400, and the automatic valves 322 and 422 installed in the suction lines 321 and 421 are crossed open to reinforce the flow of the waste water circulating in the anaerobic digestion tank The sludge is circulated together with the waste water without accumulating on the inner bottom surface of the anaerobic digestion tanks 300 and 400, thereby maximizing the stirring efficiency.

1 shows an overall configuration of the present invention.
2 is a block diagram briefly showing the connection relationship of the components of the present invention.
3 is a plan view and a side view showing the structure of the first suction line unit 320 of the first anaerobic digestion tank 300. This structure is the same as that of the second suction line unit 420 of the second anaerobic digestion tank 400 Lt; / RTI >

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

The present invention relates to an anaerobic treatment apparatus applied to a facility for treating leachate generated from food wastes (negative wastewater).

1 and 2, an acid fermentation tank is composed of a first acid fermentation tank 100 and a second acid fermentation tank 200, and the anaerobic digestion tank is composed of a first anaerobic A digester 300 and a second anaerobic digester 400.

In this acid fermentation tank, the acidic fermentation microbes are used for acid fermentation treatment of the negative wastewater supplied from the negative wastewater collecting tank, and the negative wastewater from the negative wastewater collecting tank is supplied to the first acid fermentation tank 100 and the second acid fermentation tank 200 , The acid fermentation treatment by the acid fermentation microorganisms is performed individually in the first acid fermentation tank 100 and the second acid fermentation tank 200, respectively.

If any one of the first acid fermentation tank 100 and the second acid fermentation tank 200 is to be maintained, the waste water that has been supplied to the maintenance-requiring site is blocked and the acid fermentation process is continued You can proceed.

The first underwater stirrer 120 is installed under the inner space of the first acid fermentation tank 100 and serves to stir the negative wastewater. A mechanical stirring apparatus in which a stirring blade is rotated by a motor is used.

In the case of the second acid fermentation tank 200, negative wastewater supplied from the wastewater collection tank is subjected to acid fermentation treatment through the acid fermentation microorganisms in the same manner as in the first acid fermentation tank 100, A second submerged stirrer 220 for stirring the negative wastewater is installed.

The first anaerobic digestion tank injection pump 110 serves to supply the anaerobic digested waste water from the acid fermentation tank 100 to the first anaerobic digestion tank 300 and the second anaerobic digestion tank injection pump 210 The second anaerobic digestion tank 400 is connected to the second anaerobic digestion tank 400 through the acid fermentation tank 200.

The first anaerobic digestion tank 300 is connected to the second anaerobic digestion tank 400 through a second acid fermentation tank 200. The first anaerobic digestion tank 400 is connected to the second anaerobic digestion tank 400, ), And reacts with the anaerobic microorganisms by receiving the acidic fermentation treated wastewater.

The first anaerobic digestion tank circulation pump 310 sucks the wastewater from the lower part of the inner space of the first anaerobic digestion tank 300 and supplies it to the upper part of the inner space of the first anaerobic digestion tank 300 to forcibly circulate the wastewater to generate anaerobic microorganisms Thereby increasing the reaction efficiency. The first anaerobic digestion tank circulation pump 310 is installed outside the first anaerobic digestion tank 300, and can be easily maintained and repaired, and the management cost can be reduced.

One end of the first suction line part 320 is connected to the inlet side of the first anaerobic digestion tank circulation pump 310 and the other end of the first suction line part 320 is connected to the lower part of the inner space of the first anaerobic digestion tank 300 And serves as a passage for sucking the waste water from the lower part of the inner space of the first anaerobic digestion tank 300.

One end of the first supply line 330 is connected to the outlet of the first anaerobic digestion tank circulation pump 310 and the other end of the first supply line 330 is connected to the upper part of the inner space of the first anaerobic digestion tank 300 And serves as a passage for discharging the waste water circulating to the upper part of the inner space of the first anaerobic digestion tank 300.

The second anaerobic digester circulation pump 410, the second suction line unit 420 and the second supply line unit 430 are also connected to the first anaerobic digestion tank circulation pump 310, the first suction line unit 320, 1 supply line unit 330, and redundant description will be omitted.

The first branch line 340 branches from the first supply line 330 and is connected to the upper part of the inner space of the second anaerobic digestion tank 400 through the first branch line 340, May be transferred to the second anaerobic digestion tank 400. If a problem arises in the first anaerobic digestion tank 300 during operation of the apparatus, the waste water of the first anaerobic digestion tank 300 may be transferred to the second anaerobic digestion tank 300, It can be transferred to the digester 400 and processed. That is, it is possible to cope with an emergency in an emergency and to continuously process the device, thereby improving the reliability of the device.

In the first branch line 340, a first opening / closing valve 345 is provided to open / close the first branch line 340. That is, when the first opening / closing valve 345 is closed, the waste water is not transferred from the first anaerobic digestion tank 300 to the second anaerobic digestion tank 400, and only the forced circulation within the first anaerobic digestion tank 300 is performed. When the open / close valve 345 is opened, part of the waste water having been forcedly circulated in the first anaerobic digestion tank 300 is supplied to the second anaerobic digestion tank 400 by the first anaerobic digestion tank circulation pump 310.

The second branch line 440 and the second open / close valve 445 are connected to the second anaerobic digestion tank circulation pump 410 through the second anaerobic digestion tank circulation pump 410, 1 anaerobic digestion tank 300.

One end of the first transfer line 350 is connected to the first supply line 330 and the other end of the first transfer line 350 is installed above the inner space of the first acid fermentation tank 100, And serves as a passage for conveying the waste water from the digester 300 to the first acid fermentation tank 100.

The first conveying line 350 is provided with a first conveying valve 355 and serves to open and close the first conveying line 350.

The operation pH of the acid fermentation tank is usually 4 to 5 and the operation pH of the anaerobic digestion tank is maintained in the range of 7 to 8. When the strong acidic (less than PH 3) wastewater flows into the acid fermentation tank, There is a problem in that a separate medicine cost is incurred when an alkaline chemical such as caustic soda is separately added. The first transport valve 355 is opened and the first anaerobic digestion tank circulation pump 310 is used to remove the waste water from the first anaerobic digestion tank 300 Anaerobic digestion water) is supplied to the first acid fermentation tank 100 and adjusted to a proper pH.

The first conveying valve 355 may be a valve that is automatically controlled to open and close by interlocking with a sensor for measuring PH in the first acid fermentation tank 100, though it is not shown in detail in the drawing.

In the case of the second conveying line 450 and the second conveying valve 455, the waste water (anaerobic digestion water) in the second anaerobic digestion tank 400 is supplied to the second acid fermentation tank 200 in the same manner, The acid fermentation tank 200 is adjusted to a suitable pH.

3, four first anaerobic digester circulation pumps 310 are provided, and the first supply line unit 330 is composed of two supply lines 331 and 332, And the first anaerobic digestion tank circulation pumps 310 are connected to the lines 331 and 332, respectively.

The first branch line 340 connecting the first anaerobic digestion tank 300 and the second anaerobic digestion tank 400 is connected to one of the two supply lines 331 and 332 constituting the first supply line unit 330, And the first transfer line 350 is branched at the other supply line 332 of the two supply lines 331 and 332 constituting the first supply line unit 330. [

The first suction line unit 320 is composed of four suction lines 321 as shown in FIG. 3, and each suction line 321 is connected to a different first anaerobic digestion tank circulation pump 310 . That is, one each of the first anaerobic digestion tank circulation pumps 310 is connected to each suction line 321.

An automatic valve 322 is provided for each of the suction lines 321 constituting the first suction line unit 320. An automatic valve 322 is provided for each suction line 321 constituting the first suction line unit 320, The valves 322 are alternately opened and closed by alternately repeating the opening and closing operations of the two groups, and the suction through the suction line 321 is alternately performed. That is, as shown in FIG. 3, the suction line 321 indicated by A and C and the suction line 321 indicated by B and D are alternately sucked at a predetermined time interval, so that the flow of the wastewater in the forced circulation process is strengthened to prevent accumulation of sludge And the deposited sludge is floated to circulate the sludge together with the wastewater, thereby improving the biological treatment ability.

Each of the suction lines 321 spreads evenly in the form of a tree branch under the inner space of the first anaerobic digestion tank 300. The openings of the suction lines 321 are open in different directions, (Shock) is generated and the flow is increased.

The second suction line unit 420 and the second anaerobic digestion tank circulation pump 410 are configured in the same manner as the connection structure of the first suction line unit 320 and the first anaerobic digestion tank circulation pump 310 to perform the same function do.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Addition or deletion of a technique, and limitation of a numerical value are included in the protection scope of the present invention.

100: First acid fermentation tank
110: First anaerobic digester tank infusion pump
120: first underwater stirrer
200: Second acid fermentation tank
210: Second anaerobic digester tank infusion pump
220: second underwater stirrer
300: First anaerobic digester
310: First anaerobic digester circulation pump
320: first suction line part
321: Suction line
322: Automatic valve
330: first supply line section
331,332: Supply line
340: first branch line (linked to 331)
345: first opening / closing valve
350: first return line (connected with 332)
355: first delivery valve
400: Second anaerobic digester
410: Second anaerobic digester circulation pump
420: second suction line part
421: Suction line
422: Automatic valve
430: second supply line portion
431,432: Supply line
440: second branch line (connected with 431)
445: second opening / closing valve
450: second transfer line (connected with 432)
455: second delivery valve

Claims (5)

The present invention relates to an anaerobic treatment apparatus applied to a facility for treating leachate generated from food wastes (negative wastewater)
A first acid fermentation tank 100 for acidic fermentation of the waste water supplied from the waste water collection tank through the acid fermentation microorganism;
A second acid fermentation tank 200 for acidic fermentation of the wastewater supplied from the waste water collection tank through the acid fermentation microorganisms;
A first anaerobic digestion tank (300) for receiving negative fermentation treated wastewater through the first acid fermentation tank (100) and reacting with anaerobic microorganisms;
A second anaerobic digestion tank (400) for receiving the acidic fermentation treated wastewater while passing through the second acid fermentation tank (200) and reacting with the anaerobic microorganism;
A first anaerobic digestion tank injection pump 110 for supplying the wastewater from the first acid fermentation tank 100 to the first anaerobic digestion tank 300;
A second anaerobic digester tank infusion pump 210 for supplying the waste water from the second acid fermentation tank 200 to the second anaerobic digestion tank 400;
A first underwater stirrer 120 installed under the inner space of the first acid fermentation tank 100 to stir the waste water;
A second underwater stirrer 220 installed under the inner space of the second acid fermentation tank 200 to stir the waste water;
A first anaerobic digestion tank circulation pump 310 for sucking the wastewater from the lower part of the inner space of the first anaerobic digestion tank 300 and supplying the sucked wastewater to the upper part of the inner space of the first anaerobic digestion tank 300;
A first suction line part 320 connected to the inlet side of the first anaerobic digestion tank circulation pump 310 at one end, and a lower end installed at the lower part of the inner space of the first anaerobic digestion tank 300;
A first supply line unit 330 connected at one end to the outlet of the first anaerobic digestion tank circulation pump 310 and at the other end installed above the interior space of the first anaerobic digestion tank 300;
A second anaerobic digestion tank circulation pump 410 for sucking the wastewater from the lower part of the inner space of the second anaerobic digestion tank 400 and supplying it to the upper part of the inner space of the second anaerobic digestion tank 400;
A second suction line part 420 connected at one end to the inlet side of the second anaerobic digestion tank circulation pump 410 and at the other end below the internal space of the second anaerobic digestion tank 400;
A second supply line part 430 connected to the outlet side of the second anaerobic digestion tank circulation pump 410 at one end and installed at the upper part of the internal space of the second anaerobic digestion tank 400 at the other end;
A first branch line (340) branched from the first supply line part (330) and connected to an upper part of the inner space of the second anaerobic digestion tank (400);
A first opening / closing valve (345) installed in the first branch line (340) for opening / closing the first branch line (340);
A second branch line 440 branched from the second supply line unit 430 and connected to an upper portion of the inner space of the first anaerobic digestion tank 300;
A second open / close valve (445) installed in the second branch line (440) for opening / closing the second branch line (440);
One end of the first anaerobic digestion tank 300 is connected to the first feed line 330 and the other end of the first anaerobic digestion tank 300 is installed above the inner space of the first acid fermentation tank 100, A first conveying line 350 for conveying the toner image to the recording medium 100; And
One end of the second anaerobic digestion tank 400 is connected to the second feed line 430 and the other end of the second anaerobic digestion tank 400 is installed above the inner space of the second acid fermentation tank 200, A second conveying line 450 for conveying the first conveying line to the first conveying line 200;
Wherein the anaerobic treatment apparatus comprises an anaerobic treatment unit for anaerobic treatment using multifunctional suction circulation. The method of claim 1,
A plurality of first anaerobic digester circulation pumps 310 are provided,
The first supply line unit 330 is composed of two supply lines 331 and 332 and the supply lines 331 and 332 are connected to different first anaerobic digestion tank circulation pumps 310,
The first branch line 340 branches from one of the two supply lines 331 and 332 constituting the first supply line unit 330,
The first transfer line 350 is branched from the other one of the two supply lines 331 and 332 constituting the first supply line unit 330,
A plurality of second anaerobic digester circulation pumps 410 are provided,
The second supply line unit 430 is composed of two supply lines 431 and 432. The supply lines 431 and 432 are connected to different second anaerobic digestion tank circulation pumps 410,
The second branch line 440 branches from one of the two supply lines 431 and 432 constituting the second supply line unit 430,
Wherein the second feed line (450) is branched from the other feed line (432) of the two feed lines (431, 432) constituting the second feed line part (430) Processing device. 3. The method of claim 2,
A first transport valve (355) provided in the first transport line (350) for opening and closing the first transport line (350); And
A second conveying valve (455) installed on the second conveying line (450) and opening / closing the second conveying line (450);
Wherein the anaerobic treatment apparatus further comprises a multifunctional suction circulation system. 3. The method of claim 2,
The first suction line unit 320 includes:
Each of the suction lines 321 is connected to a first anaerobic digestion tank circulation pump 310 which is different from the first anaerobic digestion tank circulation pump 310,
An automatic valve 322 is provided for each suction line 321 constituting the first suction line unit 320,
The automatic valves 322 provided for each of the suction lines 321 constituting the first suction line unit 320 are alternately opened and closed alternately in pairs so that the automatic valves 322 can be opened and closed through the suction line 321 Suction is alternately performed,
The second suction line part (420)
Each of the suction lines 421 is connected to a second anaerobic digester circulation pump 410 which is different from the first suction line 421,
An automatic valve 422 is provided for each suction line 421 constituting the second suction line unit 420,
The automatic valves 422 provided for each of the suction lines 421 constituting the second suction line unit 420 are alternately opened and closed alternately in pairs so that the automatic valves 422 are opened alternately through the suction line 421 Wherein the suction is performed alternately. 5. The method of claim 4,
Each of the suction lines 321 and 421 extends in the form of a tree branch under the inner space of each of the first anaerobic digestion tank 300 and the second anaerobic digestion tank 400 and the inlet of each of the suction lines 321 and 421 extends in different directions Wherein the anaerobic treatment apparatus is open to the anaerobic treatment apparatus using multifunctional suction circulation.

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